T-cell engagers (TCEs) direct cytotoxic T-cell response towards tumor cells by binding simultaneously to a tumor-associated antigen (TAA) on target cells and to CD3 on T-cells, thereby forming an artificial immune synapse. They have been shown to be very potent anti-tumor drugs, as exemplified by blinatumomab, an α-CD19 x α-CD3 bispecific. However, the development of TCEs for hematological and solid tumors has been hampered by several factors, amongst them severe toxicity, elicited by on-target/off-tumor recruitment of T-cells and cytokine release syndrome (CRS).
In order to overcome this challenge, an anti-CD3 Prodrug DARPin® (CD3-PDD) has been developed, consisting of a mouse cross-reactive EGFR-binder and a CD3-binder, linked via a protease-cleavable linker to an anti-idiotypic anti-CD3 binder (termed blocker hereafter). This α-EGFR x α-CD3 x blocker Prodrug is unable to bind and recruit T-cells in its non-cleaved state, but is designed to become activated in the tumor microenvironment upon cleavage of the linker by tumor-associated proteases.
A control Prodrug DARPin® with a non-cleavable linker showed neither tumor cell killing, nor T-cell activation at concentrations >1'000-fold over the EC50 of the active, non-blocked TCE DARPin® in in vitro tumor cell killing and T-cell activation assays. In contrast, a CD3-PDD containing a cleavable linker was partially activated by proteases secreted from the tumor cells (HCT 116). Pre-treatment of the CD3-PDD with recombinant protease prior to the in vitro assay fully activated the molecule, with EC50 values comparable to the active, non-blocked TCE.
Next, an in vivo proof-of-principle study was performed in a human colon carcinoma xenograft model (HCT 116) using immunodeficient mice humanized with hematopoietic stem cells (CD34+) and optimized for the presence of human myeloid cells. Due to the mouse cross-reactivity of the EGFR-binder, this animal model allowed to assess both anti-tumor efficacy and safety (therapeutic window). The cleavable CD3-PDD demonstrated a robust anti-tumor activity, similar to the one observed with active, non-blocked TCE. Most importantly, while the active, non-blocked TCE elicited strong toxicity, leading to loss of animals and requiring treatment stop, the cleavable CD3-PDD could be dosed without significant safety findings.
In summary, a conditionally activated CD3-PDD shows similar efficacy but none of the toxicity of the active, non-blocked TCE. Our approach therefore holds great promise for the development of future CD3-PDD as therapeutics, enabling the utilization of less tumor-specific targets for highly potent TCEs. Ultimately, the ability of the versatile DARPin® technology to generate tailor-made anti-idiotypic DARPin® molecules can unlock novel therapeutic design spaces, which we are exploring beyond the conditionally activated CD3-PDD format.
Citation Format: Andreas Bosshart, Julia Katharina Ahlskog, Aline Eggenschwiler, Dieter Schiegg, Yvonne Grübler, Sandra Wandel, Simon Fontaine, Maria Paladino, Susanne Mangold, Tanja Hospodarsch, Alexandra Neculcea, Chloé Iss, Christel Herzog, Bernd Schlereth. A solution to T-cell engager toxicity: An anti-CD3 Prodrug DARPin (CD3-PDD) shows no toxicity, but potent anti-tumor activity in a humanized mouse model [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr 1890.
